JP4885240B2 - Method and apparatus for lifting a snowplow - Google Patents

Description

  This application claims priority to US Patent Application No. 60 / 744,590, filed Feb. 2, 2006, under the name Method and Apparatus For Plow Without Auxiliary Light Kit. The present invention relates to the technical field of methods and apparatus for snow removal, and more particularly, such that when the snowplow is in the raised position, the snowplow is bent out of the track of the vehicle headlight. The present invention relates to a method and an apparatus for lifting a snowplow. The present invention eliminates the need for separate snowplow lighting.

  It is widely known to provide a snowplow assembly for use in moving snow and ice from roads, roadways, parking lots, and other such surfaces. Typically, the snowplow assembly is attached to a vehicle such as a light truck. Usually, the snowplow can be moved by the driver / operator of the vehicle by operating a control system in the passenger compartment of the vehicle. Depending on the specific design of the snowplow assembly and associated controls, many movements of the snowplow may be possible, but snowplow movement is almost always the same as using a snowplow to remove snow from the ground. A lowered “use” position, and a raised “carry” position where the snowplow can be carried by the vehicle (without touching the ground) until it is required again Including adjustments between them.

  In general, a snowplow assembly includes (1) a support frame that can be coupled to a vehicle, (2) a snowplow frame that is pivotally coupled to the support frame that supports the snowplow, and (3) a normally hydraulic system. And an adjustment mechanism for use in adjusting the position of the snowplow frame member. To adjust the snowplow from the use position to the transport position, the snowplow frame (and hence the snowplow) is lifted and pivoted around the support frame.

  Such known snowplow assemblies generally work well for their intended purpose, but have drawbacks. One drawback is that while the snowplow is in the raised transport position, the snowplow blocks the light coming from the vehicle headlights. To solve this problem, it is widely known to provide an auxiliary lighting system as part of the snowplow assembly. This option solves the lighting problem, but is expensive and cumbersome to install.

US Patent Application No. 60 / 76,590

  The present invention includes embodiments that solve lighting problems and other problems associated with snowplows in a novel way that eliminates the need for an auxiliary lighting system.

According to one embodiment of the present invention, a method for adjusting a snowplow includes:
(A) providing a snowplow assembly, the snowplow assembly comprising: 1) a support frame for use in connecting the snowplow assembly to an associated vehicle; and 2) operably connected to the support frame. At least one lift frame member having an uppermost portion and a lowermost portion, 3) at least one snowplow frame member engaging the lift frame member, and 4) operably on the snowplow frame member A snowplow having a snowplow operating axis coupled thereto, and 5) an adjustment mechanism for use in adjusting the position of the snowplow frame member on the lift frame member, the method further comprising: ,
(B) connecting the snowplow to the snowplow assembly so that the snowplow is positioned substantially in front of the associated vehicle;
(C) By pulling the snowplow frame member down to the lowest part of the lift frame member, the snowplow is positioned to remove snow located directly in front of the associated vehicle, and the snowplow operating axis is approximately on the ground. Parallel steps;
(D) lifting the snowplow frame member to the uppermost part of the lift frame member,
Step (d) is therefore: (e) pivoting the snowplow frame member on the uppermost part of the lift frame member so that the snowplow operating axis is at an angle A1 between 10 ° and 90 ° with respect to the ground. Including steps
After step (e)
Pivoting the snowplow frame member on the uppermost portion of the lift frame member in a direction opposite to step (d);
Lowering the snowplow frame member to the lowest portion of the lift frame member.
According to another embodiment of the present invention, a snowplow assembly includes:
The snowplow assembly having a support frame for use in connecting the snowplow assembly to an associated vehicle;
A first lift frame member having an uppermost portion and a lowermost portion operatively coupled to the support frame;
A first snowplow frame member that engages the first lift frame member;
The snowplow operably connected to the first snowplow frame member and having a snowplow operating axis so that the snowplow can be positioned in front of the associated vehicle;
A first snowplow frame member is on the bottom portion of the first lift frame member, the snowplow is positioned to remove snow located directly in front of the associated vehicle, and the snowplow operating axis is on the ground An adjustment mechanism used to move the snowplow between a first position which is substantially parallel and a second position where the snowplow is raised above the ground;
The position of the first snowplow frame member on the first lift frame member is adjusted to a second position where the first snowplow frame member is on the top portion of the first lift frame member. The machine is raised and includes an adjustment mechanism for use in adjusting to a second position where the snowplow operating axis is at an angle A1 between 10 ° and 90 ° to the ground.

  One advantage of the present invention is that it eliminates the need for auxiliary snowplow lighting.

  Another advantage of the present invention is that the snowplow assembly cost can be significantly reduced without sacrificing quality.

  Another advantage of the present invention is that the weight of the snowplow assembly is reduced.

  The present invention may take physical forms in specific parts and arrangements of parts, and the embodiments are described in detail herein and in the accompanying drawings, which form a part of this specification. Show.

  Referring now to the drawings, which are presented for purposes of illustrating various embodiments of the invention only and not for purposes of limiting the invention, FIGS. 1 shows a snowplow assembly 50 including a snowplow 100 according to FIG. The snowplow assembly 50 can be attached to the front of the vehicle 10, which can be any type or size of vehicle that is suitably designed to carry the snowplow assembly 50. However, the snowplow assembly 50 of the present invention is lighter than a conventional snowplow assembly, and therefore the assembly is usually referred to as a “snowplow ready” such as a Sport Utility Vehicle (SUV). It should be noted that it can be installed in and used with a vehicle that is not considered. The vehicle 10 includes conventional headlights (only one headlight 12 is shown), each creating a headlight beam 14. The purpose and application of the headlight 12 is widely known and therefore will not be described in detail herein.

  1-3, the snowplow assembly 50 can include a support frame 52 that supports the snowplow 100 through all its movements and when transported. The vehicle mounting structure 54 is not necessary for the present invention, but can be fixed to the vehicle 10 by a known method. In this case, the support frame 52 and hence the snowplow assembly 50 can be selectively attached to and detached from the vehicle mounting structure 54 in any manner selected by appropriate engineering judgment.

  Referring now to FIGS. 1-10, the snowplow assembly 50 is also illustrated with two of at least one lift frame member 56 (56a, 56b) used to adjust the height of the snowplow 100. Which is further described below. Each lift frame member 56 has an uppermost portion 58 and a lowermost portion 60. The lowermost portion 60 can be operably connected to the support frame 52 by welding, bolting, or other known methods. In other embodiments, the lift frame member 56 can be made with the support frame 52 as a single component. Each lift frame member 56 may have at least one track 62 (two of 62a and 62b are shown) for receiving a track engagement device 200 described below. In one embodiment, the tracks 62 a, 62 b are formed on the outer surfaces on both sides of the lift frame member 56. Each track 62 may be generally S-shaped with a straight central portion 64 and upper and lower portions 66, 68 curved in opposite directions. In one embodiment, the straight central portion 64 is substantially perpendicular to the ground 16. For purposes described further below, the upper portion 66 can be curved toward the snowplow 100 and the lower portion 68 can be bent away from the snowplow 100. Each track 62 may have a stop position 70 that is used to stop the upward movement of the track engagement device 200 along the track 62. 70a refers to the stop position for the track 62a, and 70b refers to the stop position for the track 62b. In one embodiment, each stop position 70 includes a curved surface as shown herein, but other methods of stopping movement of the track engagement device 200 can also be used. At least a portion of the curved upper portion 66 can be used as the stop position 70 in one embodiment. At least one of the tracks 62 may have a second stop position 72 that is used to stop the downward movement of the track engagement device 200 along the track 62, as will be described further below. explain. The second stop position 72 can also include a curved surface, as shown here, in one embodiment. In a more specific embodiment, the second stop position 72 can include a groove 74 formed in the surface of the track 62. Each lift frame member 56 may also have a contact surface 76 to be used as described further below. If two lift frame members 56 a, 56 b are used, they can be positioned on both sides of the support frame 52. Support member 78 can be coupled between lift frame members 56a and 56b to increase the structural stability of the unit. The support member 78 can also be used in one embodiment to help lift the snowplow 100, as will be described below.

  With continued reference to FIGS. 1-10, the snowplow assembly 50 can also have a snowplow frame 80 that is used to support the snowplow 100 against the lift frame 56. The connection of the snowplow 100 to the snowplow frame member 80 can be any connection selected by appropriate engineering judgment. The snowplow 100 can, for example, be movable around the vertical snowplow axis VA and / or movable around the horizontal axis HA (sometimes referred to as “tripping”), as is well known to those skilled in the art. . One embodiment of a torsion spring 11 that can be used with the present invention is shown in FIGS. When the snowplow 100 is being used to remove snow on the ground 16, the snowplow 100 assumes that the snowplow is not tripping around the horizontal axis HA and is substantially parallel to the ground 16. It has an operation axis OA. The snowplow frame 80 can have at least one contact surface 81 that is used to contact the contact surface 76 of the lift frame member 56, as will be further described below. In one embodiment, the contact surface 81 extends inwardly from one or both snowplow frames 80a, 80b. In other embodiments, contact surface 81 is the outer surface of support member 83 that extends between snowplow frames 80a and 80b.

  Still referring to FIGS. 1-10, the snowplow frame 80 can also include the aforementioned track engagement device 200 for engaging the track (s) 62 of the lift frame 56. In one embodiment shown herein, the snowplow frame 80 includes a snowplow frame member 80a operatively engaged with the lift frame member 56a and a snowplow frame member operably engaged with the lift frame member 56b. 80b. The snowplow frame members 80a, 80b may be moved along the track 62 of the lift frame members 56a, 56b using the track engagement device 200. More specifically, each snowplow frame member 80a, 80b can include a pair of coupling devices 82a, 82b having track engaging surfaces that engage the tracks 62a, 62b. The coupling devices 82a, 82b may be of any design selected by appropriate engineering judgment, but in the embodiment shown here, the coupling devices are such that the snowplow frame 80 is relative to the lift frame 56. Rollers 84a and 84b having surfaces that roll along tracks 62a and 62b, respectively.

  With continued reference to FIGS. 1-10, the snowplow assembly 50 may also have an adjustment mechanism 90 that is used to adjust the position of the snowplow frame 80, and thus the snowplow 100, on the lift frame 56. it can. The adjustment mechanism 90 can include a lift cylinder 92 mounted between the support frame 52 and the snowplow frame 80. The lift cylinder 92 can be a hydraulic cylinder and can be operated by a conventional hydraulic system (not shown). The particular connection between the lift cylinder 92 and the snowplow frame member 80 can be any selected by appropriate engineering judgment. In the embodiment shown here, the first connector 30 is pivotally attached to the snowplow frame 80 at one end and pivotally attached to the second connector 51 at the opposite end. The second connector 51 has one end pivotally attached to the first connector 30 and an opposite end pivotally attached to the distal end of a rod 96 extending from the lift cylinder 92. .

  With continued reference to FIGS. 1-10, the adjustment mechanism 90 can be used to adjust the snowplow frame 80 and the snowplow 100 to at least two positions. The first position shown in FIG. 1 is such that the snowplow frame members 80a, 80b are positioned on the lowermost portions 60, 60 of the lift frame members 56a, 56b and the snowplow 100 is positioned to remove snow, In addition, the snowplow operating axis OA is substantially parallel to the ground 16. “Positioned to remove snow” means that the snowplow 100 is positioned to be used to remove snow from the ground 16 without the need for further adjustment to the lift frame 56. To do. The second position shown in FIG. 3 is that the snowplow frame members 80 a, 80 b are located on the top portions 58, 58 of the lift frame members 56 a, 56 b and the snowplow operating axis OA is 10 relative to the ground 16. This is the position at an angle A1 between 0 ° and 90 °. In the embodiment shown here, the angle A1 is between 30 ° and 50 °. The second position is ideal for transporting the snowplow assembly 50 to the next point of use. One benefit of adjusting the snowplow frame 80 and the snowplow 100 to the second position is that the snowplow 100 does not interfere with the headlight beam 14 at this position. As a result, there is no requirement for an auxiliary lighting system as part of the snowplow assembly 50 that is currently required. This reduces the cost of the snowplow assembly 50 and reduces the mass (weight) of the snowplow assembly 50, so using the snowplow assembly 50 in a vehicle that is not normally considered a good choice for snowplow. Can do.

  With continued reference to FIGS. 1-10, the operation of the snowplow assembly 50 will now be described. In order to lift the snowplow frame 80 and the snowplow 100 from the conventional snowplow position shown in FIG. 1, the operator uses a control system, described below, selected by appropriate engineering judgment to lift the snowplow frame 80. Use to activate lift cylinder 92. The lift cylinder 92 moves the track engaging surfaces of the coupling devices 82a, 82b upward along the tracks 62a, 62b. The generally vertical orientation of the central portions 64, 64 of the lift frame members 56 a, 56 b allows for efficient lifting of the snowplow 100. It should be noted that the snowplow operating axis OA remains substantially parallel to the ground 16 when the snowplow frame 80 and the snowplow 100 are continuously lifted along the central portions 64, 64. As a result, the snowplow 100 reaches the position shown in FIG. 2 where the snowplow 100 blocks the headlight beam 14. When the snowplow 100 is continuously pulled up, each connecting device 82a is moved to the curved upper portion 66 of the track 62a and reaches the stop position 70a. As the snowplow 100 is further lifted, the snowplow frame 80 is pivoted in the direction D1 around each coupling device 82a (at this stage, each coupling device 82a has finished moving along the track 62a, while each The coupling device 82a is positioned in the stop position 70a). While the snowplow frame 80 pivots in the direction D1 around each coupling device 82a, each coupling device 82b continues to move generally upward along the track 82b. This movement continues until each coupling device 82b moves to reach the stop position 70b. This is the position shown in FIG. Note that the snowplow 100 does not interfere with the headlight beam 14 in this position. As a result, this is ideal in a vehicle “storage” position carrying the vehicle 10 and snowplow assembly 50.

  With continued reference to FIGS. 1-10, in the illustrated embodiment, the location of the center of gravity labeled with the CG for the portion of the snowplow assembly 50 that is to be adjusted is determined when the snowplow 100 is raised and lowered. Ensure that the snowplow frame 80 tends to pivot in direction A1. This rough location for the CG helps to keep the coupling devices 82a, 82b against the tracks 62a, 62b when the snowplow 100 is raised or lowered. To prevent the snowplow frame 80 from pivoting toward the vehicle 10, a stop member 101, which in one embodiment is a bolt, is used. If the snowplow frame 80 pivots to some extent, a portion of the snowplow assembly 50, in one embodiment, the first connector 30 contacts the stop member 101 and, therefore, further pivoting action is prevented. .

  Still referring to FIGS. 1-10, to pull down the snowplow frame 80 and snowplow 100 from the storage position shown in FIG. 3, the operator activates the lift cylinder 92 again. When the lift cylinder 92 operates, the snowplow frame 80 pivots around each coupling device 82a in a direction D2 opposite to the direction D1, while each coupling device 82b exits from the stop position 70b. And then move generally downward along track 82b. In one embodiment, the operation of the lift cylinder 92 required to pivot the snowplow frame 80 in the direction D2 is simply to pull the rod 96 down. In other embodiments, the lift cylinder 92 movement necessary to pivot the snowplow frame 80 in direction D2 is a slight pull up of the rod 96 that moves the coupling device 82b out of the stop position 82b. is there. This embodiment allows the contact surface 81 of the snowplow frame 80 to contact the contact surface 76 of the lift frame member 56 as the snowplow frame 80 is lifted. This contact makes it easier for the coupling device 82b to move out of the stop position 82b and move downward along the track 62b. The lift cylinder 92 is then pulled down. In either embodiment, when the snowplow 100 is continuously pulled down, the coupling device 82a is lowered along the track 62 through the central portions 64, 64 of the lift frame members 56a, 56b to the lower portions 68, 68. It becomes possible to move to. As described above, in one embodiment, the track 62 may have a second stop position 72. In the embodiment shown in FIG. 3, the stop position 72 receives a coupling device 82b. This allows the snowplow frame 80 to pivot in the direction D2 around the coupling device 82b. This is useful, for example, when the ground 16 is a snow-cleaved slope facing downward from the front of the vehicle 10, and thus more than the position used when the ground 16 is relatively flat or horizontal. It is beneficial to be able to bend the snowplow 100 down.

  Referring now to FIGS. 1-3, the particular control system used to operate the snowplow assembly 50 can be any selected by appropriate engineering judgment. In one embodiment, the control system 220 includes a hydraulic system 222 and a controller 230. The hydraulic system 222 provides hydraulic fluid for operating the lift cylinder 92 and any other hydraulically actuated component, as is well known in the art. The controller 230 is a device used by the operator to operate the hydraulic system 222, and hence the associated hydraulic components, and any other components as required. The specific control device 230 may be any of the conventional types such as a control device fixed in the operator's room of the vehicle 10 or a control device that is not attached and therefore can be easily moved by the operator as needed. You can also The controller 230 can be wired to the snowplow assembly 50 and can use radio frequency (RF) technology or other wireless technology. The control device 230 can label (1) a control button ("L" as shown here) that, when pressed, pivots the snowplow 100 left about the vertical snowplow axis VA. (2) A control button that, when pressed, pivots the snowplow 100 in the right direction about the vertical snowplow axis VA (can be labeled “R” as shown here) , (3) a control button (which can be labeled “U” as shown here) that, when pressed, moves the snowplow 100 upwards, and (4) when pressed, Various conventional control buttons 232 can be included, including control buttons that move down (which can be labeled “D” as shown here).

  With continued reference to FIGS. 1-3, in the illustrated embodiment, the controller 230 includes two additional control buttons for use with the present invention. The actual labeling can be arbitrary as needed, but one control button 232a can be labeled "Flip" and the other control button 232b can be "non- It can be labeled “Unflip”. The reverse button 232a is pressed by the operator when it is desired to adjust the snowplow 100 to the second position shown in FIG. In this case, the snowplow 100 is not simply lifted, but the snowplow frame 80 is pivoted (reversed) around the coupling device 82a in the direction D1 as described above. The non-reverse button 232b is pressed by the operator when it is desired to adjust the snowplow 100 to leave the second position shown in FIG. In this case, the snowplow frame 80 is pivoted (non-inverted) in the direction D2 around the coupling device 82a as described above. Pressing one or both buttons 232a, 232b can activate a timer with an appropriate hydraulic device to perform the required function. For example, pressing the non-inverted button 232b can raise the snowplow frame 80 for 3 seconds (or some other predetermined time) to allow the snowplow frame 80 to pivot as described above.

  Referring now to FIGS. 14-17, the snowplow assembly 50 can include other components and operations not yet described. A snowplow 100 can be attached to the snowplow frame 80 using a pin pull mechanism 300. Handle 302 is used to pull bar 304 connected to pins 306 and 308. The spring 310 can be used to keep the pins 306, 308 biased towards the installed position. To remove the snowplow 100, the handle 302 is pulled against the force of the spring 310. This moves the draw bar 304 and the pins 306, 308 are released sufficiently to remove the snowplow 100. More specifically, when the draw bar 304 is moved, the surface 350 exceeds the surface 360. At this point, the pins 306, 308 can be rotated to lock 10 or 20 degrees clockwise (as shown here) or on the surface 360. To return the pin in, rotate the pin counterclockwise and the pin will snap back in.

  Referring now to FIG. 18, in another embodiment, each lift frame member 56a, 56b may have a partially enclosed track 62 as shown here. Each lift frame member 56a, 56b may have a track 26 on one side thereof. The snowplow frame 80 is connected to the track 26 so that the snowplow frame 80 and hence the snowplow 100 can be moved along the track 26. The snowplow frame member 80 can have a pair of connection points 336, 336 that are received within the track 26. The connection points 336, 336 can be of any design selected by appropriate engineering judgment, such as rollers, as shown herein. The connection points 336 and 336 can be moved along the track 26 in the same manner as described above.

  Various embodiments have been described above. It will be apparent to those skilled in the art that the methods and apparatus described above can incorporate changes and modifications without departing from the general scope of the invention. It is intended to include all such modifications and variations as long as they fall within the scope of the appended claims or their equivalents.

1 is a side view of a vehicle with a snowplow assembly according to the present invention, with the snowplow shown in a lowered conventional snowplow position. FIG. 2 is a side view similar to that shown in FIG. 1 but showing the snowplow in a slightly raised position. FIG. 2 is a side view of the snowplow similar to that shown in FIG. 1 but showing the snowplow in a raised inverted position where the snowplow does not interfere with the headlight beam. 1 is a side perspective view of a snowplow assembly of the present invention shown separated from a vehicle. FIG. 5 is a side perspective view of the snowplow assembly shown in FIG. 4 showing the snowplow in a lowered position. FIG. 5 is a close-up side perspective view of the snowplow assembly shown in FIG. 4 showing the snowplow in the raised but not inverted position. FIG. 5 is a close-up side perspective view of the snowplow assembly shown in FIG. 4 showing the snowplow in the raised and inverted position. FIG. 5 is a top perspective view of a portion of the snowplow assembly shown in FIG. 4. FIG. 5 is a side perspective view of a portion of the snowplow assembly shown in FIG. 4. FIG. 5 is a close-up top view of a portion of the snowplow assembly shown in FIG. 4. FIG. 5 is a top view of a torsion spring providing a tripping action to the snowplow assembly shown in FIG. 4. It is a side view of the torsion spring shown in FIG. It is an end surface perspective view of the torsion spring shown in FIG. 1 is a side perspective view of a mechanism that can be used to attach a snowplow to a snowplow frame. It is an end surface perspective view of the mechanism shown in FIG. FIG. 15 is a close-up top perspective view of the mechanism shown in FIG. 14. FIG. 15 is a close-up top perspective view of the mechanism shown in FIG. 14. It is a side perspective view showing other embodiments.

Claims (7)

A method for adjusting a snowplow (100), comprising:
(A) providing a snowplow assembly (50) for use in connecting the snowplow assembly (50) to the associated vehicle (10); A support frame (52) and 2) at least one lift frame member (56) having an uppermost portion (58) and a lowermost portion (60) operatively coupled to the support frame (52). 3) at least one snowplow frame member (80) that engages the lift frame member (56); and 4) a snowplow operating shaft operably connected to the snowplow frame member (80). A snow remover (100) having OA) and 5) an adjustment mechanism (90) for use in adjusting the position of the snow remover frame member (80) on the lift frame member (56). Cage, wherein the method further,
(B) coupling the snowplow (100) to the snowplow assembly (50) such that the snowplow (100) is positioned substantially in front of the associated vehicle (10);
(C) By pulling down the snowplow frame member (80) to the lowermost part (60) of the lift frame member (56), the snowplow (100) is placed in front of the associated vehicle (10). Positioned to remove directly located snow and the snowplow operating axis (OA) is substantially parallel to the ground (16);
(D) lifting the snowplow frame member (80) to the uppermost portion (58) of the lift frame member (56),
Step (d) then: (e) pivoting the snowplow frame member (80) on the uppermost portion (58) of the lift frame member (56), so that the snowplow operating axis (OA) is Coming at an angle (A1) between 10 ° and 90 ° with respect to the ground (16),
After step (e)
Pivoting the snowplow frame member (80) on the uppermost portion (58) of the lift frame member (56) in a direction opposite to step (d);
Lowering the snowplow frame member (80) to the lowermost portion (60) of the lift frame member (56). Steps (a) and (2) include providing a contact surface (76) to the lift frame member (56);
Steps (a) and (3) comprise providing a contact surface (81) to the snowplow frame member (80);
The step of pivoting the snowplow frame member (80) on the uppermost portion (58) of the lift frame member (56) in a direction opposite to step (d) comprises the snowplow frame member (80 2) contacting the contact surface (81) of the lift frame member (56) with the contact surface (76) of the lift frame member (56). The snowplow assembly (50) having a support frame (52) for use in connecting the snowplow assembly (50) to the associated vehicle (10), and operably connected to the support frame (52); A first lift frame member (56) having an uppermost portion (58) and a lowermost portion (60), and a first snowplow frame member engaging the first lift frame member (56) (80) and the snowplow (100) are operatively connected to the first snowplow frame member (80) so that the snowplow (100) can be positioned in front of the associated vehicle (10), and the snowplow operating shaft (OA) The snow remover (100) having
The first snowplow frame member (80) is on the lowermost portion (60) of the first lift frame member (56) and the snowplow (100) is in front of the associated vehicle (10). A first position where the snowplow operating axis (OA) is substantially parallel to the ground (16) and a snowplow (100) above the ground (16). An adjustment mechanism (90) used to move the snowplow (100) between the raised second position and
The position of the first snowplow frame member (80) on the first lift frame member (56) is such that the first snowplow frame member (80) is the first lift frame member (56). ) To the second position on the top portion (58), the snowplow (100) is raised, and the snowplow operating axis (OA) is 10 ° to the ground (16). Said adjustment mechanism (90) for use in adjusting to a second position at an angle (A1) between 90 °,
The first lift frame member (56) includes first and second tracks (62);
The first snowplow frame member (80) includes first and second engagement surfaces (200) that engage the first and second tracks (62), respectively;
The first and second tracks (62) each include a stop position (70);
When the first snowplow frame member (80) is in the second position, the first track engaging surface (200) is moved to the stop position (70 on the first track (62). ) And the second track engagement surface (200) is engaged at the stop position (70) on the second track (62),
A snowplow assembly wherein each of said stop positions (70) includes a curved surface. The snowplow assembly (50) having a support frame (52) for use in connecting the snowplow assembly (50) to the associated vehicle (10), and operably connected to the support frame (52); A first lift frame member (56) having an uppermost portion (58) and a lowermost portion (60), and a first snowplow frame member engaging the first lift frame member (56) (80) and the snowplow (100) are operatively connected to the first snowplow frame member (80) so that the snowplow (100) can be positioned in front of the associated vehicle (10), and the snowplow operating shaft (OA) The snow remover (100) having
The first snowplow frame member (80) is on the lowermost portion (60) of the first lift frame member (56) and the snowplow (100) is in front of the associated vehicle (10). A first position where the snowplow operating axis (OA) is substantially parallel to the ground (16) and a snowplow (100) above the ground (16). An adjustment mechanism (90) used to move the snowplow (100) between the raised second position and
The position of the first snowplow frame member (80) on the first lift frame member (56) is such that the first snowplow frame member (80) is the first lift frame member (56). ) To the second position on the top portion (58), the snowplow (100) is raised, and the snowplow operating axis (OA) is 10 ° to the ground (16). Said adjustment mechanism (90) for use in adjusting to a second position at an angle (A1) between 90 °,
A second lift frame member (56) having an uppermost portion (58) and a lowermost portion (60) operatively coupled to the support frame (52);
A second snowplow frame member (80) engaging the second lift frame member (56);
The snowplow (100) is operably coupled to the second snowplow frame member (80);
The adjustment mechanism (90) moves the position of the second snowplow frame member (80) on the second lift frame member (56) to at least two positions:
1) The second snowplow frame member (80) is on the lowermost portion (60) of the second lift frame member (56) and the snowplow (100) is in the associated vehicle (10) A first position that is positioned to remove snow located directly in front of and wherein the snowplow operating axis (OA) is substantially parallel to the ground (16), and
2) The second snowplow frame member (80) is on the top portion (58) of the second lift frame member (56) and the snowplow operating axis (OA) is the ground (16) A snowplow assembly for use in adjusting to a second position at said angle (A1) between 10 ° and 90 ° to.   A support member (83) having a first end attached to the first snowplow frame member (80) and a second end attached to the second snowplow frame member (80). And wherein the support member (83) is also adapted to contact a first contact surface formed on the first lift frame member (56) And a second contact surface adapted to contact a second contact surface formed on the second lift frame member (56). The snowplow assembly (50) having a support frame (52) for use in connecting the snowplow assembly (50) to the associated vehicle (10), and operably connected to the support frame (52); A first lift frame member (56) having an uppermost portion (58) and a lowermost portion (60), and a first snowplow frame member engaging the first lift frame member (56) (80) and the snowplow (100) are operatively connected to the first snowplow frame member (80) so that the snowplow (100) can be positioned in front of the associated vehicle (10), and the snowplow operating shaft (OA) The snow remover (100) having
The first snowplow frame member (80) is on the lowermost portion (60) of the first lift frame member (56) and the snowplow (100) is in front of the associated vehicle (10). A first position where the snowplow operating axis (OA) is substantially parallel to the ground (16) and a snowplow (100) above the ground (16). An adjustment mechanism (90) used to move the snowplow (100) between the raised second position and
The position of the first snowplow frame member (80) on the first lift frame member (56) is such that the first snowplow frame member (80) is the first lift frame member (56). ) To the second position on the top portion (58), the snowplow (100) is raised, and the snowplow operating axis (OA) is 10 ° to the ground (16). Said adjustment mechanism (90) for use in adjusting to a second position at an angle (A1) between 90 °,
When the first snowplow frame member (80) is in the second position, the snowplow operating axis (OA) is at an angle (A1) between 30 ° and 50 ° with respect to the ground (16). ) Snowblower assembly at A support frame (52) for use in connecting the snowplow assembly (50) to the associated vehicle (10);
A first lift frame member (56) having an uppermost portion (58) and a lowermost portion (60) operatively coupled to the support frame (52);
A first snowplow frame member (80) that engages the first lift frame member (56);
The snow removal device operably connected to the first snow removal frame member (80) and having a snow removal operation axis (OA) so that the snow removal device (100) can be positioned in front of the associated vehicle (10). Machine (100),
The first snowplow frame member (80) is on the lowermost portion (60) of the first lift frame member (56) and the snowplow (100) is in front of the associated vehicle (10). A first position where the snowplow operating axis (OA) is substantially parallel to the ground (16), and the first snowplow frame member (80) is positioned to remove snow located directly on the ground. The snowplow between a second position on the top portion (58) of the first lift frame member (56) and where the snowplow (100) is raised above the ground (16). An adjustment mechanism (90) used to move (100),
The adjustment mechanism (90) includes the first snowplow so that the snowplow operating axis (OA) is at an angle (A1) between 10 ° and 90 ° with respect to the ground (16). A frame member (80) is pivoted in a first direction (D1) on the uppermost portion (58) of the first lift frame member (56), and the snowplow (100) is moved to the first lift frame member (56). Prior to moving to the position, the first snowplow frame member (80) is second on the top portion (58) of the first lift frame member (56) opposite the first direction. A snowplow assembly characterized by being pivoted in the direction (D2).